Matthew Sands

Matthew Sands

Matthew L. Sands Los Alamos ID badge photo
Born (1919-10-20)October 20, 1919
Oxford, Massachusetts
Died September 13, 2014(2014-09-13) (aged 94)
Santa Cruz, California
Nationality American
Fields Accelerator physics
Institutions
Alma mater Massachusetts Institute of Technology
Clark University
Rice University
Thesis The meson component of cosmic radiation [1] (1948)
Doctoral advisor Bruno Rossi
Known for Co-author of The Feynman Lectures on Physics
Notable awards Robert R. Wilson Prize (1998)

Matthew Linzee Sands (October 20, 1919 – September 13, 2014) was an American physicist and educator best known as a co-author of the Feynman Lectures on Physics. A graduate of Rice University, Sands served with the Naval Ordnance Laboratory and the Manhattan Project's Los Alamos Laboratory during World War II.

After the war Sands studied cosmic rays for his doctorate at the Massachusetts Institute of Technology (MIT) under the supervision of Bruno Rossi. Sands went to the California Institute of Technology (Caltech) in 1950, and helped build and operate its 1.5 GeV electron synchrotron. He became deputy director for the construction and early operation of the Stanford Linear Accelerator Center (SLAC) in 1963. Sands. He later joined the University of California, Santa Cruz (UCSC) as a professor of physics, and served as its vice chancellor for science from 1969 to 1972. In 1998, The American Physical Society awarded him the Robert R. Wilson Prize "for his many contributions to accelerator physics and the development of electron-positron and proton colliders."[2]

Early life and education

Matthew Linzee Sands was born in Oxford, Massachusetts, on October 20, 1919. His parents were Linzee Sands and Beatrice Goyette, both of whom were bookkeepers. He had a brother, Roger, and a sister, Claire, who was seven years younger. As a 12-year-old Boy Scout, Sands was motivated by his scoutmaster, who was a radio amateur, to build his own shortwave radio receiver. With the aid of information from the Radio Amateur's Handbook, he constructed it out of parts scavenged from old radios. He was encouraged to study mathematics and science by his In high school, math teacher, John Chafee, a graduate of Brown University.[3]

After high school, Sands entered Clark University, where he studied physics and mathematics, and received his Bachelor of Arts (B.A.) in 1940. At Clark, his physics professors were Theodore P. Jorgensen,[4] who became famous for his book "The Physics of Golf", and Percy M. Roope,[5] who participated in the rocket experiments of Robert H. Goddard. As part of a job subsidized at 35 cents per hour by the National Youth Administration, they assigned him to build physics equipment in the machine shops, where he became familiar with the drill press, lathe and other metalworking tools.[3]

At Rice University, Sands took graduate courses in relativity, statistical mechanics, and thermodynamics from Harold A. Wilson, who was the first chair of the physics department. He also did experimental studies of ferromagnetism. At Rice he met his first wife, Elizabeth, an undergraduate student there.[3] He received his Master of Arts (M.A.) in physics from Rice.[6]

World War II

In 1941, Sands went to the Naval Ordnance Laboratory in Washington, D.C., where he learned more about electronics under Joseph F. Keithley.[7] Keithly and Sands developed two influence mines, from which three patents were derived.[8] They performed sea tests of a working prototype, but for unknown reasons, the program was stopped.[3]

By 1943, Sands had become impatient with the Navy's bureaucracy. After discussing the situation with Wilson, he appeared unannounced in Santa Fe, New Mexico, at the office of Dorothy McKibben, who had been designated to meet newcomers to Los Alamos Laboratory. After she made a telephone call to the personnel office, which had just received a desperate call for electronics people, Sands was bussed to Los Alamos. To his surprise, he was met by Jorgenson, who had just joined the Manhattan Project after leaving Clark and going to Nebraska. He immediately took Sands to the library to read Robert Serber's Los Alamos Primer, which introduced him to the basic physical principles of nuclear fission as they were known at the time, and their implications for nuclear weapon design.[3]

By this time, Sands had extensive experience with electronics and was immediately thrust into the electronics group, whose job was to make instruments for the whole laboratory, and whose head was Darol Froman. Within this group, his close collaborators were William Elmore,[9] William Higinbotham, and Ernest Titterton. Anybody who had an instrumentation problem would come to the group for help. As a result, Sands worked with Luis Alvarez, Robert Bacher, Hans Bethe, Richard Feynman, Otto Frisch, Bruno Rossi, Emilio Segrè, Robert Walker and Robert Wilson. Many of these famous physicists played important roles in his later career. In particular, he formed a close relationship with Rossi, with whom he later decided to work on his post-war Ph.D. degree.[3] Rossi was most interested in the group's nuclear electronics equipment: pulse counters and amplifiers, discriminators, and scalers. In this area, Sands designed and patented a pulse height analyzer,[10] and with Otto Frisch and Elmore, a pulse amplifier.[11] He also created electronics for more general purposes, such as precise temperature regulation,[12] and control of electroplating operations.[13]

Sands was at the Trinity nuclear test site near Alamogordo, New Mexico, where he worked with Walker on a piezoelectric pressure measurement of the atmospheric shock wave produced by "the gadget". This was a prototype of the Fat Man weapon later dropped on Nagasaki. Their instrumentation worked well during the test explosion of 108 tons of TNT, but no information was obtained during Trinity because an unexpected rain shower the night before soaked the apparatus.[3]

To raise public consciousness of issues raised by Trinity, David Hawkins, William Higinbotham, Philip Morrison, Robert Wilson and others formed the Los Alamos Association of Atomic Scientists. As a founding member, Sands put out its weekly newsletter. On November 30, 1945, this organization merged with similar groups within the Manhattan Project and at Oak Ridge to form the Federation of Atomic Scientists, which soon changed its name to the Federation of American Scientists (FAS).[14] In 1946, Sands and Elmore wrote "Electronics: Experimental Techniques", which was published in 1949 by McGraw-Hill. This book presented many ideas and circuits developed at Los Alamos. and became a standard reference for post-war nuclear instrumentation.[15]

Massachusetts Institute of Technology

After the success of the Manhattan Project and the Radiation Laboratory, the Massachusetts Institute of Technology (MIT) moved into a new era of "big science" funded by the US government.[16] This era was foretold in a 1945 report, Science, The Endless Frontier,[17] written by Vannevar Bush, who was an MIT graduate and influential head of the wartime Office of Scientific Research and Development. MIT's expansion into physics was encouraged by its president Karl Compton and by the head of the physics department, John C. Slater. One part, the expansion of nuclear physics, was spearheaded by physics professor Jerrold R. Zacharias, who joined the Los Alamos Laboratory late in the war, where he recruited Bruno Rossi and Victor Weisskopf as MIT professors.[18]

Within the new Laboratory for Nuclear Science, headed by Zacharias, Rossi was assigned to create a cosmic ray research group. He recruited four young scientists who had been at Los Alamos, including Sands, and two who had been in the Radiation Laboratory, as Ph.D. candidates. All were more mature than typical graduate students, with several years of wartime research experience. They were paid a stipend similar to that of a postdoctoral researcher, which enabled them to support families during their graduate studies. The laboratory was funded by the Office of Naval Research.[3]

With Rossi as his academic advisor, and with the aid of a Boeing B-29 Superfortress aircraft borrowed from the United States Air Force, Sands carried out his thesis research on the slow muon component of cosmic rays. He measured the intensity of low energy muons as a function of altitude up to 40,000 feet (12,000 m), and derived their spectrum at production and as they propagated through the atmosphere.[19] This information was important, because most atmospheric cosmic rays are muons. He received his Ph.D. in physics from MIT in 1948. Sands then joined the faculty as an assistant professor, and continued his cosmic ray research in Rossi's group.[20]

Another project of the Laboratory for Nuclear Science was a synchrotron particle accelerator, which was designed to accelerate electrons to an energy of 350 MeV. It was funded by the Office of Naval Research and built under the supervision of Ivan A. Getting. He was a professor of electrical engineering, who had worked at the Radiation Laboratory on the extremely successful SCR-584 radar. Although its construction began in 1946, the accelerator had not begun to work in 1949. In response, Zacharias asked Sands to assist.[3] This was Sands's introduction to accelerator physics, and with his help the machine became operational early in 1950.[21]

In 1948, Sands divorced his first wife, Elizabeth in Reno, Nevada. She remained in Weston, Massachusetts, with their two children, while Sands married Eunice Hawthorne, a sister-in-law of his high school math teacher, John Chafee, and moved with her into MIT's Westgatehousing units for married students.[22][23] In early 1950, in his words:

... my ex-wife had a father who had a fair amount of money, and they decided to make trouble for me, and were going to throw me in jail as a bigamist because they claimed my (Reno) divorce was not legal and so on. So I'm famous around MIT as the person who had to leave in the middle of the night and not come back.[3]

Caltech

Sands went to the California Institute of Technology (Caltech), where he helped build and operate 1.5 GeV electron synchrotron. He was the first to demonstrate, both theoretically and experimentally, the role of quantum effects in electron particle accelerators. He also studied beam instabilities, wake fields, beam-cavity interactions, and other phenomena.[6]

In 1963, Sands became deputy director for the construction and early operation of the Stanford Linear Accelerator Center (SLAC). When Richard Feynman was deciding whether or not to accept the 1965 Nobel Prize—due to a disdain for the added notoriety it might bring—Sands convinced Feynman that not accepting it would bring even more attention.[24] Sands later joined the University of California, Santa Cruz (UCSC) as a professor of physics, and served as its vice chancellor for science from 1969 to 1972.[2] After retiring from UCSC in 1985, Sands worked as a consultant for SLAC and also as a consultant for Bay View Elementary School and Santa Cruz High School in Santa Cruz, California, to develop computer systems and physics lab activities for students.[2]

From 1960 to 1966, Sands served on the Commission on College Physics, which carried out a national program to modernize physics instruction in the colleges and universities of the United States. He helped Feynman and Robert B. Leighton write the 1964 physics textbook Feynman Lectures on Physics, based upon the lectures given by Feynman to undergraduate students at Caltech between 1961 and 1963.[3] He was involved in the creation of Kresge College, where he met Freya Kidner, a student there who subsequently became his wife.[25] He received a Distinguished Service Award from the American Association of Physics Teachers in 1972, and in 1998 The American Physical Society awarded him the Robert R. Wilson Prize "for his many contributions to accelerator physics and the development of electron-positron and proton colliders."[2]

Sands died in Santa Cruz on September 13, 2014. He was survived by his wife Freya, his daughter, Michelle, sons Michael and Richard, and brother Roger.[25]

References

  1. Sands, Matthew (1948). The meson component of cosmic radiation (Ph.D.). NASA. Retrieved October 23, 2014.
  2. 1 2 3 4 Stephens, Tim (April 20, 1998). "Professor emeritus wins physics prize". University of Santa Cruz Currents.
  3. 1 2 3 4 5 6 7 8 9 10 11 Aaserud, Finn (May 4–5, 1987). "Oral History Transcript — Dr. Matthew Sands". Center for History of Physics; The Niels Bohr Library & Archives. American Physical Society. Retrieved January 22, 2013.
  4. "Theodore "Ted" P. Jorgensen". The Scarlet. University of Nebraska-Lincoln. April 15, 2010. Retrieved January 23, 2013.
  5. Wilford, John Noble (October 5, 1982). "A Salute To Long Neglected 'Father Of American Rocketry'". New York Times (The New York Times Company). Retrieved January 23, 2013.
  6. 1 2 "Matthew Sands biography". American Physical Society. Retrieved September 14, 2014.
  7. Keithley Instruments Inc. History. International Directory of Company Histories, Vol. 16 (St. James Press). 1967.
  8. Keithley and Sands Patents: 297969: Microphone For The Measurement Of Transient Pressures In A Body Of Water1,4185556: Mine firing system, 3044398: Pressure-Time Responsive Electronic Firing Device; US Patent and Trademark Office
  9. Pray, Rusty (February 1, 2003). "William C. Elmore, 93, physics professor". philly.com (The Philadelphia Inquirer). Retrieved January 31, 2013.
  10. Sands, Matthew L. (July 19, 1948). "Pulse Height Analyzer". Patent number: 2529666. US Patent and Trademark Office. Retrieved January 31, 2013.
  11. Sands, Matthew L.; William C. Elmore; Otto R. Frisch (March 19, 1945). "Pulse Amplifier". Patent number: 2531164. US Patent and Trademark Office. Retrieved January 31, 2013.
  12. Sands, Matthew L. (September 1, 1950). "Automatic Temperature Regulator". Patent number: 2646544. US Patent and Trademark Office. Retrieved January 31, 2013.
  13. Sands, Matthew L. (August 17, 1948). "Electroplating Control System". Patent number: 2584816. US Patent and Trademark Office. Retrieved January 31, 2013.
  14. Goldsmith, H. H.; S. Rabinowitch (September 1, 1946). "Federation of American Scientists". Bulletin of the Atomic Scientists (Atomic Scientists of Chicago). p. 24. Retrieved January 31, 2013.
  15. Elmore, William C.; Sands, Matthew L. (1949). Electronics: experimental techniques (PDF). Volume 1 of National nuclear energy series: Los Alamos Project (McGraw-Hill Book Co.). p. 417. Retrieved January 31, 2013.
  16. "The History of the MIT Department of Physics". Big Physics at MIT : 1946-1970. Massachusetts Institute of Technology. Retrieved February 2, 2013.
  17. Bush, Vannevar (July 1945). Science The Endless Frontier. Office of Scientific Research and Development (Washington: United States Government Printing Office). Retrieved February 2, 2013.
  18. Goldstein, Jack S. (1992). A Different Sort of Time: the Life of Jerrold R. Zacharias, Scientist, Engineer, Educator. Cambridge, Massachusetts: MIT Press. pp. 66–70. ISBN 026207138X. OCLC 24628294.
  19. Sands, Matthew (October 5, 1949). "Low Energy Mesons in the Atmosphere". Physical Review 77 (2): 180–193. Bibcode:1950PhRv...77..180M. doi:10.1103/PhysRev.77.180. Retrieved February 2, 2013.
  20. "Compton Gives Promotions to 9 Professors" (PDF). The Tech (MIT). April 6, 1948. p. 1. Retrieved February 4, 2013.
  21. "Synchrotron Passes Tests" (PDF). The Tech (MIT). February 7, 1950. pp. 1–3. Retrieved February 3, 2013.
  22. Smith, Nancy DuVergne; Debbie Levey (August 12, 2012). "How WWII Veterans Changed the MIT Landscape". Slice of MIT blog. MIT Alumni Association. Retrieved February 2, 2013.
  23. Sands, Matthew L.; Joseph F. Keithley (December 30, 1949). "Patent which gives 11 Westgate, Cambridge, MA as address for Sands". Patent number: 3044398. US Patent and Trademark Office. Retrieved February 3, 2013.
  24. Feynman, Richard (1985). Surely You're Joking, Mr. Feynman! (Adventures of a Curious Character. New York: W.W. Norton. p. 200. ISBN 9780393019216.
  25. 1 2 "Matthew Linzee Sands Obituary". Santa Cruz Sentinel. September 17, 2014. Retrieved September 18, 2014.
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